Concept of Operations: Mitchell Hammock Road Adaptive Traffic Signal Control...
Transcript of Concept of Operations: Mitchell Hammock Road Adaptive Traffic Signal Control...
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Concept of Operations:
Mitchell Hammock Road
Adaptive Traffic Signal Control System Red Bug Lake Road from Slavia Road to SR 426 Mitchell Hammock Road from SR 426 to Lockwood Boulevard Lockwood Boulevard from Mitchell Hammock Road to CR 419
Prepared by: City of Oviedo
Draft 1: June 2015
Document Approval Status
City of Oviedo Approval Signature Date
Seminole County Approval Signature Date
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Contents
1. Scope .................................................................................................................................... 3
2. User-Oriented Operational Description............................................................................... 4
3. How the Existing System Works .......................................................................................... 5
4. Network Characteristics ....................................................................................................... 5
5. Traffic Characteristics .......................................................................................................... 6
6. Signal Grouping .................................................................................................................... 6
7. Operating Agencies .............................................................................................................. 6
8. Existing Architecture and Infrastructure ............................................................................. 6
9. What are the Limitations of the Existing System? ............................................................... 8
10. How the System will be Improved ................................................................................... 9
11. Statement of Objectives for the Improved System ......................................................... 9
12. Description of Strategies to Be Applied by the Improved System ................................. 12
13. Operational Needs ......................................................................................................... 13
14. Measuring Progress Towards Needs Satisfaction .......................................................... 14
15. System Overview ............................................................................................................ 14
16. Adaptive Operational Environment ............................................................................... 15
17. Operational Scenarios .................................................................................................... 16
18. Failure Scenarios ............................................................................................................ 19
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1. Scope This document addresses the system engineering needs for the Mitchell Hammock Road Adaptive Traffic
Signal System. The signal system will make use of adaptive coordinated traffic signal technology to
improve traffic conditions along the corridor of Red Bug Lake Road from Slavia Road to SR 426, Mitchell
Hammock Rd from SR 426 to Lockwood Blvd, and Lockwood Boulevard from Mitchell Hammock Road to
CR 419 as depicted in the illustration below.
Figure 1 Corridor Map
This Concept of Operations explains, at a high level, how the system will operate and defines the relative
roles and responsibilities of the various participants in the system at each stage in the development of the
project. The intended audience for the document includes both public and private sector partners
responsible for planning, design, implementation, operations and maintenance of the system. This
document is also intended to provide the required information for Federal and Florida Department of
Transportation approval. Finally the document is expected to be used by the selected vendor as guidance
for system design and implementation.
Figure 1 Corridor Map
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2. User-Oriented Operational Description
Overview
Adaptive traffic signal control technology makes use of sensors, communications and a control system to
enable traffic signal timings to be in accordance with the variation in traffic flow. The system will also
provide better support for public transit and emergency vehicle priority by minimizing disruption to
coordination along the corridor in the event of a priority call. The overall effect of applying the technology
will be to improve the reliability of travel times experienced through the corridor, reduce fuel
consumption, reduce emissions and improve]s the driver experience by reducing the number of stops.
The figure below shows a high level architecture description of the system.
Figure 2 High Level System Architecture
The implementation will make use of existing traffic control hardware in order to preserve sunk
investment in capital equipment and minimize implementation costs. Each intersection is currently
equipped with the following equipment:
NEMA ATC Controllers
Conflict monitor / Malfunction Management Units
Load switches
Loop, Video, or Microwave Detection
Fiber Optic Ethernet Based Network Switch
Adaptive control configuration for
the corridor
Vehicle detection
Adaptive control processor
Connectors Equipment panel
Relay
Traffic controller
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This will be supplemented through the acquisition of special purpose control hardware designed to
support adaptive traffic signal control and the installation of traffic sensors at suitable locations along the
corridor. Traffic signals will be controlled by on street controllers which in turn will be linked back to the
regional traffic management center. This will allow traffic conditions to be monitored remotely from the
regional traffic management center for special events to be managed remotely by operator intervention
at the management center.
3. How the Existing System Works The current system is connected back to the traffic management center via the fiber interconnect. This
allows equipment monitoring and also plan selection. The current control strategy is based on Time of
Day plan selection. Under the auspices of this control strategy different timing plans are selected based
on the current time of day. The timing plans were developed based on snapshot traffic counts and do not
reflect evolving traffic conditions.
4. Network Characteristics The nature of the existing road network is arterial with major intersections with SR 426, SR 434 and CR
419 along with signalized ramp access for the SR 417 toll expressway. Land use along Red Bug Lake Road
is primarily commercial. For Mitchell Hammock land use is primarily residential with some commercial
uses. Commercial land uses consist of retail as well as business operations.
Table 1 provides a summary of the signalized intersections being addressed by the project. Table 2
provides a summary of the distances between intersections.
Table 1 List of Intersections
Intersection
Red Bug Lake Road and Slavia Road
Red Bug Lake Road and Dovera Drive
Red Bug Lake Road and Oviedo Mall Boulevard
Red Bug Lake Road and SR 417 Southbound Ramp
Red Bug Lake Road and SR 417 Northbound Ramp
Red Bug Lake Road / Mitchell Hammock Road and SR 426
Mitchell Hammock Road and SR 434 (Alafaya Trail)
Mitchell Hammock Road and Clara Lee Evans Way / City Plaza Way
Mitchell Hammock Road and Oviedo Boulevard
Mitchell Hammock Road and Lake Rogers Boulevard / Kingsbridge Drive
Mitchell Hammock Road and Alafaya Woods Boulevard / Reformation Drive
Mitchell Hammock Road and Lockwood Boulevard
Lockwood Boulevard and CR 419
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Table 2 Distances between intersections
From Intersection To Intersection Miles
Red Bug Lake / Slavia Red Bug Lake / Dovera 0.60
Red Bug Lake / Dovera Red Bug Lake / Oviedo Mall 0.21
Red Bug Lake / Oviedo Mall Red Bug Lake / SR 417 SB 0.25
Red Bug Lake / SR 417 SB Red Bug Lake / SR 417 NB 0.14
Red Bug Lake / SR 417 NB Red Bug Lake/M. Hammock / SR 426 0.31
Red Bug Lake/M. Hammock / SR 426 Mitchell Hammock / SR 434 1.08
Mitchell Hammock / SR 434 Mitchell Hammock / Clara Lee Evans 0.25
Mitchell Hammock / Clara Lee Evans Mitchell Hammock / Oviedo 0.22
Mitchell Hammock / Oviedo Mitchell Hammock / Lake Rogers 0.44
Mitchell Hammock / Lake Rogers Mitchell Hammock / Alafaya Woods 0.28
Mitchell Hammock / Alafaya Woods Mitchell Hammock / Lockwood 0.58
Mitchell Hammock / Lockwood Lockwood / CR 419 0.24
Total corridor length 4.6
5. Traffic Characteristics This roadway is a heavily trafficked arterial, with variable traffic flows. It features bidirectional peaks
requiring a sophisticated approach to signal coordination. The corridor is a major arterial for the City of
Oviedo.
6. Signal Grouping The intersections are sufficiently close that they may be coordinated together under all traffic conditions.
Since there are no groups of intersections that are separated by a sufficiently large distance it is
recommended that all intersections are coordinated together.
7. Operating Agencies The operating agency for the adaptive traffic control system will be Seminole County. The signal control
equipment along the corridor will be connected using the existing Seminole County fiber Ethernet based
network back to the Seminole County Traffic Management Center (TMC). The City of Oviedo will be
provided a remote workstation for monitoring the operations of the signals under their jurisdiction. The
relationship between the proposed system and the Central Florida Regional ITS Architecture is described
in the following section.
8. Existing Architecture and Infrastructure The following table summarizes the function and interfaces supported by the Seminole County TMC.
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Table 3 Functions and Interfaces
Coordinate emergency traffic signal control with the county EOC/warning points
Coordinate HRI signal adjustments, and provide track status information (e.g., blockage) to rail operators and local traffic operations
Coordinate traffic information and traffic control with the FDOT District 5 RTMC
Coordinate traffic information with the Seminole County TMC and the FDOT District 5 RTMC
Operate traffic signal systems, including CCTVs, signals, and sensors, for Seminole County and municipalities including City of Oviedo
Provide transit signal priority for regional transit providers using roadside devices
Information Dissemination for Central Florida Regional ITS Architecture
Coordinate emergency plans, incident responses, and resources with the county EOC/warning points
Coordinate evacuation and reentry plans with the county EOC/warning points
Provide traffic information to travelers using private companies; county and city public information systems; and the media
Receive AMBER Alerts and other wide area alert information from the county EOC/warning points
Incident Management (Traffic and Maintenance) for Central Florida Regional ITS Architecture
Perform network surveillance for detection and verification of incidents on County and City roads, and send traffic/incident information and traffic images to county fire/EMS/sheriff agencies, the FHP, the county EOC, and local fire/EMS/police agencies
Provide incident information to travelers using traffic information devices on county roads, and through local ISPs, Web sites, and the local media
Receive incident information, incident response status, and resource requests from the county EOC/warning points
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The following block diagram shows how this system will fit within the Central Florida Regional ITS
Architecture and the interfaces that are supported.
Figure 3 Fit with Central Florida Regional ITS Architecture
Note that the gray box labeled “Seminole / Oviedo Field Equipment” is where the system will reside within
the overall Central Florida Regional ITS Architecture. The operation of the traffic signals will be managed
from the Seminole County TMC using a center to center communication link to City of Oviedo, with
maintenance activities supported by Seminole County.
9. What are the Limitations of the Existing System?
Traffic signal control hardware along the corridor are serviceable. Existing traffic signal controllers are
Naztec ATC Controllers current monitored and operated via central software. However due to traffic
conditions it is necessary to implement an adaptive traffic control system. The corridor has been retimed
several times in the past and yet progression is still limited. The variation in demand along the corridor
require a more sophisticated solution. The current traffic controllers cannot support such a solution
without the purchase of additional hardware and/or software.
Counties and cities
FDOT Statewide
Lynx
FDOT D5 RTMC
Sunguide
FDLE
Local media and venue promoters
MetroPlan
NOAA
City of Oviedo
TMC
ISPs
Seminole / Oviedo field equipment
County public safety
County EOCs
Seminole County TMC
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10. How the System will be Improved In broad terms, the general approach to improving the system is through the introduction of an adaptive
coordinated capability to existing hardware along the corridor. This is to be achieved through the
procurement of additional hardware and software that will work with existing controllers to support
additional adapters and coordinated functionalities.
11. Statement of Objectives for the Improved System This section is focused on describing the operational objectives that will be satisfied by the envisioned
adaptive operation.
Operational objectives for the signals to be coordinated are as follows:
1. Smooth the flow of traffic along coordinated routes and improve travel time reliability 2. Maximize the throughput along the corridor by making the best use of available green
time 3. Manage queues, to prevent excessive queuing from reducing efficiency 4. Preserve the legacy hardware and software to protect sunk investment in capital
equipment 5. Enable traffic signal timings to be better aligned with variations in traffic flow 6. Minimize installation cost for adaptive control strategies through the reuse of existing
hardware and software 7. Maximize the efficiency of the corridor under emergency and public transit priority
situations through minimization of transition periods and the selection of the appropriate post priority traffic movements
8. The system must incorporate frequent pedestrian operation into routine adaptive operation
9. Operator training will be provided to enable effective and efficient operations and management of the system from the County TMC
10. Provide traffic and operational data 11. Equipment failure management
Smooth Flow
This objective seeks to provide a green band or pipeline along the corridor. For this particular corridor it
is particularly important to achieve bidirectional coordination and to accommodate variable traffic flows.
The corridor traffic exhibits bidirectional peaks and considerable variability. This will be achieved by
ensuring that the relationship between the intersections and signal timings are such that once a platoon
starts moving it rarely slows or stops. This may involve holding a platoon at one intersection until it can
be released and not experience downstream stops. It may also involve operating non-coordinated phases
at a high degree of saturation (by using the shortest possible green), within a constraint of preventing or
minimizing phase failures and overflow of turn bays with limited length, and with spare time in each cycle
generally reverting to the coordinated phases.
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Maximize Throughput
This objective seeks to provide a broad green band along an arterial road, both directions, to provide the
maximum throughput along the coordinated route without causing unacceptable congestion or delay side
streets.
Manage Queues
The adaptive traffic signal control algorithm should also take account queue management requirements.
This is particularly important for this corridor where most of the intersection spacing is less that 0.3 mile.
One of the primary objective is to ensure that queues do not block upstream. This often requires
constraints on phase lengths to ensure that a large platoon does not enter a short block if it must be
stored within that block and wait for a subsequent green phase. The adaptive algorithm should have the
ability to manage queues in such a manner.
Preserve legacy hardware and software
Existing hardware and software for traffic signal control is perfectly serviceable and does not require to
be replaced. The current configuration can support adaptive coordinated traffic signal control. The desired
implementation will make maximum use of existing hardware and software and superimpose appropriate
capabilities to support adaptive traffic signal control. This will ensure that the cost of installation for
adaptive traffic signal control is minimized.
Enable traffic signal timings to be better aligned with variations in traffic flow
The primary objective in implementing adaptive traffic signal control along this corridor is to better align
traffic signal timings with variations in traffic flow. There are significant variations in traffic control along
the corridor over the course of the day. Time-of-Day control strategies do not have the flexibility to
optimize traffic signal control along the corridor.
Minimize installation costs
It is essential that sunk investment in traffic signal control equipment along the corridor is preserved.
Therefore it is an important requirement of the project that existing hardware for traffic signal control be
utilized in the new solution.
Maximize the efficiency of the corridor under emergency and public transit priority situations
The corridor currently features emergency vehicle and public transit vehicle priority equipment. This
enables emergency and public transit vehicles to call for priority at each intersection. Under the current
traffic signal control regime this introduces a loss of available green time due to the recovery period after
priority has been granted. The objective is to minimize transitional green time losses.
Incorporate Frequent Pedestrian Calls
The system is to accommodate the incorporation of frequent pedestrian calls at any of the intersections.
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Operator training will be provided to enable effective and efficient operations and management of the system from the TMC
Training will be provided to enable operators to conduct the following activities:
Troubleshooting the system
Preventive maintenance and repair of equipment
System configuration
Administration of the system
System calibration
Training delivery shall include: printed course materials and references, electronic copies of presentations
and references and delivered at the TMC.
Provide traffic and operational data
One of the major advantages of an adaptive coordinated traffic control system using the latest technology
is the ability to collect a range of valuable data. This data can be used for operational management of the
traffic signal system and also be used as input to a performance management system. The system will be
expected to provide a range of traffic and operational data as specified in the requirements.
Existing Travel Time and Video Surveillance systems deployed within the corridor will be supplemented
with addition equipment to provide enhanced monitoring of corridor operation.
Equipment failure management
The system will be expected to support a range of equipment failure management features. These will
include failure of the adaptive processor, failure of the communication system and failure of other
hardware and software. Failure management features will be expected to comply with those specified in
requirements.
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12. Description of Strategies to Be Applied by the Improved System This section describes the adaptive coordination and control strategies that may be employed to achieve
the operational objectives.
Provide a Pipeline or green wave in both directions
Providing a pipeline along a coordinated route will support the two objectives of minimizing stops along
a route and maximizing throughput along the route. The provision of a pipeline along a coordinated route
can be achieved by a system based on a common cycle length, and also by a system that provides
coordination bands toward and away from a critical intersection without using a common cycle length. A
non-cycle-length-based or non-sequential system is preferred. This will define the bandwidth of the
pipeline to match the phase length of the coordinated phases at the critical intersection within a group.
Phasing at other intersections will be timed so that green is provided on the coordinated route to
accommodate the pipeline.
Distribute Phase Splits
To provide access equity, the demand for all phases will be handled equitably by serving all movements
regularly and not providing preferential treatment to coordinated movements to the extent that delays
and stops of other movements are significantly increased. To do this a system will be optimizing an
objective function that seeks to balance individual vehicle delays or some surrogate measure proportional
to delays.
Manage Queues
To manage queues, the system will allow the offsets between intersections to be set in order to allow
queues to be cleared at the end of each phase in blocks that are required to store queues during a
subsequent phase. It will provide a means to control the locations where queues are allowed to form.
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13. Operational Needs At the highest level the operational needs can be defined as follows:
Increased efficiency
Higher customer service
Improved Safety
Each of these operational needs are defined in more detail as follows:
Efficiency
Efficiency is defined by a reduction in the number of stops and the reduction in the average travel time
through the corridor. Note that the objective here is not to speed traffic but rather maintain traffic flow.
Therefore this need will also be measured through a reduction in the number of stops achieved by better
traffic signal coordination and better matching of signal timings to existing traffic flows.
Customer Service
The customer service operational need is defined as an improvement in the overall customer service
experience with the corridor. This could be measured in terms of reduction in number of stops and
reduction in delay. It can also be measured subjectively by surveying opinions of travelers who use the
corridor, developing a satisfaction rating based on the survey results.
Safety
Safety needs can be defined in terms of reduction in the number and severity of accidents on the corridor.
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14. Measuring Progress Towards Needs Satisfaction The following table summarizes the performance measures that have been identified for measuring
progress towards satisfying the needs described above. Note that some of the measures identified will
not be measured directly, but inferred through the use of simulation modeling techniques such as
Synchro.
Table 4 Performance Measures
Needs
Performance measures Efficiency Customer Service Safety
No. Of low severity accidents
No. Of stops
Arterial delay
Side-street delay
Total network delay
Average travel time
Variability in travel time
Total emissions
Total fuel consumption
15. System Overview The proposed implementation forms a component within the Seminole County traffic signal management
system operated by Seminole County. The larger system consists of a number of on-street traffic
controllers linked through a telecommunications network backbone (fiber Ethernet based interconnect)
to Seminole County TMC. The system along this corridor is currently operated using a demand responsive
strategy rather an adaptive one. This involves the creation of a number of predetermined timing plans
which are brought into play depending on threshold traffic volumes measured by sensors along the
network.
The proposed implementation will build on the success of the responsive system by adding further
sophistication in the form of adaptive control. This will obviate the need for the development and
maintenance of pre-determined timing plans. The traffic sensors will provide a continuous stream of data
regarding traffic conditions and the special-purpose algorithms built into the firmware within the new
hardware to be fitted the controllers will determine the appropriate traffic signal timings and
communicate those to the controller. The overall system operation will be operated and monitored from
the Seminole County TMC with a center to center communication link with the City of Oviedo TMC. This
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will allow the opportunity for intervention to override automated signal timings should a special event
occur.
16. Adaptive Operational Environment This section describes the physical operational environment in terms of facilities, equipment, computing
hardware, software, personnel and operational procedures necessary to operate the deployed system. It
describes the personnel in terms of their expected experience, skills and training, typical work hours, and
other activities that must be or may be performed concurrently.
To begin, the relative roles and responsibilities of each participating agency are defined. The matrix below
summarizes roles and responsibilities for these participants at the various stages in the development of
the project.
Table 5"Who Does What Matrix"
Responsibility Participant
Planning City of Oviedo / Seminole County
Design City of Oviedo / Vendor
Implementation Vendor
Operations Seminole County
Maintenance Seminole County
The figure on the next page depicts the adaptive operational environment in terms of the new hardware
and software to be installed within the overall context of the existing field system.
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Figure 4 Adaptive Operational Environment (Field)
The system will be procured by City of Oviedo, with system operations and maintenance provided by
Seminole County staff.
The operation of the adaptive system will be supported from the Seminole County TMC. This is an
established traffic management center already conducting management and supervision for the corridor
traffic signalized intersections. The new system will be operated under the auspices of the TMC. Therefore
the system will be required to support a single interface from the field to the Seminole County TMC and
a center to center communication link between the Seminole County TMC and City of Oviedo TMC will be
established to facilitate monitoring of the system.
17. Operational Scenarios To illustrate the operation of the system a number of operational scenarios have been defined. The
overall operation of the system under each of the scenarios will be described as a means of illustrating
the technical and organizational operational concept for the system. This will indicate how the hardware
and software will operate and also illustrate the respective roles and responsibilities for each of the major
participants in system operation and maintenance.
The following operational scenarios have been identified:
Normal routine operating conditions
Business Hours Operation
Off-Peak Period Operation
Major Events
Minor Incident
Major Incident
Maintenance and Failure Scenarios
Vehicle detection
New Adaptive Control
processor
New Equipment Panel
Existing Traffic controller
Fiber Interconnect or
backbone
Keyboard (For Programming)
Monitor (For Programming)
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Each of these operational scenarios are described in more detail as follows
Normal routine operating conditions
It is expected that the system will operate under these conditions for the majority of the time. Under this
scenario signal timings are automatically created and applied making use of the hardware and software
enabling adaptive traffic signal control. While the operation of the automated system will be monitored
remotely from the regional traffic management center is anticipated that there will be no requirement to
intervene in system operations.
Normal routine operating conditions can also be subdivided into a number of more detailed scenarios as
described below.
Peak Periods – Unsaturated Conditions
During typical peak periods (and other periods when traffic volumes are high), the system will select
phases that minimize delay to all movements at all intersections. The system will compare the volumes
traveling in each direction, and provide coordination in both directions. The coordination will be
implemented in a manner that provides balanced progression as far as possible in the two directions.
Where leading and lagging left turn phases are used, the system will determine the optimal phase
sequence in order to provide the best coordination. This would be linked to the direction of offset, such
as providing a lagging left turn in the heavy, coordinated direction. If the green time required for a left
turn phase is longer the time required to service a queue fully occupying the left turn bay, and the queue
would overflow and block the adjacent lane, the operator will be able to specify the phase to operate
twice per cycle in order to avoid queue overflow.
The entire corridor may be set by the operator to operate as one coordinated group, or the system may
have the freedom to operate it as one group subject to user-specified criteria, such as volume of traffic in
the peak direction exceeding a threshold.
Peak Periods – Oversaturated Conditions
During peak periods when one or more intersections are oversaturated, the primary objective of the
system will be to maximize the throughput along the corridor in the peak direction. The system will
determine the direction with peak flow and provide the maximum bandwidth possible. This will be subject
to user-specified constraints, such as allowable phase sequences, and minimum and maximum phase
times. As described in the unsaturated peak description, phase sequence of lead-lag phases, and the
operation of left turn phases will be determined by the system. The entire corridor may be set by the
operator to operate as one coordinated group, or the system may have the freedom to operate it as one
group subject to user-specified criteria, such as similar required cycle lengths in different parts of the
corridor are similar or the volume of traffic in the peak direction exceeds a threshold.
Business Hours Operation
During business hours, there will be two separate but complementary objectives: select signal timings
that ensure all movements at all intersections are accommodated equitably, while providing reasonable
coordination in both directions.
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Off-Peak Period Operation
During early mornings, evenings and parts of the weekends when traffic is lighter than during the business
hours, the coordination objectives will be similar to the business hours, although shorter green times may
be applicable. If there are green times that would provide good two-way progression and accommodate
all movements at all intersections equitably, but cannot accommodate all pedestrian movements on all
phases and stay in coordination, the system will allow shorter green times through the following actions.
If protected/permitted left turn phasing is in operation, the protected phase can be omitted under user-
specified conditions, such as very light volume or short queue lengths (determined by detector logic). The
maximum green time may be set lower than the sum of pedestrian walk and clearance times, and still
allow the pedestrian phase to operate by extending the green time when necessary without throwing the
system out of coordination.
During normal weekend traffic conditions, the system may operate in the same manner as the business
hours or as the off-peak periods.
Major Events
For this scenario it is assumed that a special event such as a sporting event is taking place requiring the
special traffic signal timings and traffic handling be applied. In this case the TMC staff will adjust the time
between green waves. The effect on traffic will be monitored making use of the sensors in the corridor
and traffic data will be relayed back to the regional traffic management center to confirm the effectiveness
of the timings and strategies being applied.
During major events, the traffic characteristics are often similar to the peak periods, either oversaturated
or unsaturated. The system will behave in a similar fashion to those periods, and data from the detection
system will determine whether unsaturated or oversaturated conditions prevail. If there is heavily
directional traffic before or after an event, the system will determine the predominant direction and
coordinate accordingly, with appropriate green times and offsets. If the event traffic is not as heavy as
peak hours, but the traffic on the corridor is still highly directional, then the system will recognize this and
provide coordination predominantly in the heaviest direction, even though the green times may be similar
to business hours (with balanced flows) green times.
The entire corridor may be set by the operator to operate as one or more coordinated groups under this
condition, or the system may have the freedom to operate it as one or more groups subject to user
specified criteria, such as similar required green times in different parts of the corridor or the volume of
traffic at key locations exceeds a threshold.
Minor Incident
Under the auspices of this scenario it is assumed that a minor incident has occurred along the corridor.
This is defined as a traffic incident that is not severe enough to require Lane closure but is of such
significance that traffic conditions have been affected along the corridor, for example a minor vehicle
collision or a stalled vehicle. In this scenario it is expected that the automated traffic control system will
be able to manage the signal timings automatically with the operation of the system being monitored
remotely at the County TMC.
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Major Incident
When a major incident occurs on I4, or at a location within the corridor, the traffic on the corridor will
change in a manner that is difficult to predict, and the response required of the system will vary depending
on the time of day, day of week and the current traffic conditions at the time the incident occurs. The
system will detect any increase in traffic volume and take the following action. If the increased volume
higher green times in order to continue to accommodate all movements at all intersections, it will increase
the green times, but only up to the maximum permitted by the operator. If the diverted traffic results in
a change in the balance of the direction of the traffic on the corridor, the progression will be changed to
match the traffic. Typically the result of these actions will be to increase certain green times and provide
a wide progression bandwidth in the direction of the diverted traffic. However, if the incident occurs at
times of lower overall traffic volumes, and it does not result in oversaturated conditions on the corridor,
the result may be that the system mimics a typical peak pattern or business hours pattern.
This type of incident will typically not result in a uniform increase in traffic in one direction for the entire
length of the corridor. Therefore, it is expected that the response of the system will be different in each
section of the corridor, depending on the location, nature and time of day of the incident. The architecture
of the system will allow each section of the system to respond independently but in a consistent manner
during incidents.
18. Failure Scenarios A number of system failure scenarios have been defined as follows:
Detector Failure
Detector reliability is a very important part of successful adaptive operation. The system will recognize a
detector failure and take appropriate action to accommodate the missing data. For a local detector failure,
the local controller will place a soft recall or maximum recall (to be user-specified) on the appropriate
phase, and issue an alarm. For a detector that influences the adaptive operation (e.g., a system detector),
the system will use data from an alternate (user-specified) detector, such as in an adjacent lane or at an
appropriate upstream or downstream location. If the number of detector failures within a specified group
exceeds a user-specified threshold, the system will cease adaptive operation and go to a fallback mode of
time-of-day operation or free operation. The fallback mode will be specified by the user based on location
and time of day. All detector failure alarms will be automatically transmitted to maintenance and
operations staff at the County TMC for appropriate attention.
Communication Failure
Communications failures will have varying effects on the operation of the system. If a communication
failure prevents the adaptive system from continuing to control one or more intersections within a
defined group, all signals within the group will revert to an appropriate, user-specified fallback mode of
operation, either time-of-day operation or free operation. The fallback mode will be specified by the user
based on location and time of day. All communication failure alarms will be automatically transmitted to
the County TMC operators for appropriate attention.
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Adaptive System Failure
There are two possible types of adaptive system failures: failure of the server or equipment that operates
the adaptive algorithms; and inability of the adaptive algorithms to accommodate current traffic
conditions. If the equipment that operates the adaptive algorithms fails, the system will recognize the
failure and place the operation in an appropriate, user-specified fallback mode, either time-of-day
operation or free operation. The fallback mode will be specified by the user based and time of day.
The adaptive system will make its decisions based largely on detector data. Occasionally, as the result of
an incident or other event outside the control of the system and outside the area covered by the system,
congestion will propagate back into the adaptive control area and the measured traffic conditions will be
outside the range of data that can be processed by the system. In locations where this is likely to occur,
the intersection detectors, or queue detectors installed specifically for this purpose, will measure
increased occupancy. In such cases, when user-specified signal timing and detector occupancy conditions
are met, the system will recognize that its response to the input data may not be appropriate, and it will
revert to an appropriate, user-specified fallback mode, either time-of-day operation or free operation.
The fallback mode will be specified by the user based and time of day.
All adaptive system failure alarms will be automatically and immediately transmitted to Seminole County
TMC and the City of Oviedo TMC operators for appropriate attention.